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Electronic structures of ferromagnetic superconductors $mathrm{UGe}_2$ and $mathrm{UCoGe}$ studied by angle-resolved photoelectron spectroscopy

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 نشر من قبل Shin-ichi Fujimori
 تاريخ النشر 2015
  مجال البحث فيزياء
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The electronic structures of the ferromagnetic superconductors $mathrm{UGe}_2$ and $mathrm{UCoGe}$ in the paramagnetic phase were studied by angle-resolved photoelectron spectroscopy using soft X-rays ($h u =400-500$). The quasi-particle bands with large contributions from $mathrm{U}~5f$ states were observed in the vicinity of $E_mathrm{F}$, suggesting that the $mathrm{U}~5f$ electrons of these compounds have an itinerant character. Their overall band structures were explained by the band-structure calculations treating all the $mathrm{U}~5f$ electrons as being itinerant. Meanwhile, the states in the vicinity of $E_mathrm{F}$ show considerable deviations from the results of band-structure calculations, suggesting that the shapes of Fermi surface of these compounds are qualitatively different from the calculations, possibly caused by electron correlation effect in the complicated band structures of the low-symmetry crystals. Strong hybridization between $mathrm{U}~5f$ and $mathrm{Co}~3d$ states in $mathrm{UCoGe}$ were found by the $mathrm{Co}~2p-3d$ resonant photoemission experiment, suggesting that $mathrm{Co}~3d$ states have finite contributions to the magnetic, transport, and superconducting properties.



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